Subset Of Primary Sensory Neurons Research Articles (Page 1)

Alloknesis refers to itch caused by normally non itch-inducing stimuli, particularly light mechanical stimuli, such as contacts with clothes or other human bodies. This symptom occurs in patients suffering from chronic itch. While it has been mainly described in patients with atopic dermatitis, it is probably present in numerous other conditions and it could induce a severe burden. Until now, it is mainly diagnosed using Von Frey filaments and validated questionnaires are lacking. Alloknesis differs from mechanical pruritus in that it is linked to sensitization to pruritus and therefore occurs in pathological conditions, whereas mechanical pruritus (triggered by the presence of insects on the skin, for example) is a physiological phenomenon. While the role of central sensitization to pruritus in alloknesis is still poorly understood, the role of peripheral sensitization is becoming clearer. Interactions between low-threshold mechanoreceptors (LTMRs) and spinal interneurons are especially involved. Both the mechanical labelled pathway and the polymodal pathway have been shown to contribute to mechanical alloknesis. The mechanical labelled pathway comprises dedicated primary sensory neurons, spinal interneurons, and projection neurons that are functionally distinct from those involved in chemical itch. The polymodal pathway relies on a subset of primary sensory neurons traditionally associated with chemical itch, which can also transduce light mechanical stimuli through the activation of the mechanosensitive ion channel PIEZO1. Both converge onto the gastrin-releasing peptide (GRP) - GRP receptor (GRPR) chemical itch pathway in the spinal cord. Alloknesis is largely unknown to healthcare professionals and even more so to patients, and is not actively investigated. The objective of reducing alloknesis should be considered a therapeutic goal. To date, it has not been investigated in clinical trials. A novel research domain is emerging concerning this symptom, which exerts a substantial impact on the daily lives of numerous patients.

Allergic rhinitis (AR) is a chronic, non-infectious condition affecting the nasal mucosa, primarily mediated mainly by IgE. Recent studies reveal that AR is intricately associated not only with type 2 immunity but also with neuroimmunity. Nociceptive neurons, a subset of primary sensory neurons, are pivotal in detecting external nociceptive stimuli and modulating immune responses. This review examines nociceptive neuron receptors and elucidates how neuropeptides released by these neurons impact the immune system. Additionally, we summarize the role of immune cells and inflammatory mediators on nociceptive neurons. A comprehensive understanding of the dynamic interplay between nociceptive neurons and the immune system augments our understanding of the neuroimmune mechanisms underlying AR, thereby opening novel avenues for AR treatment modalities.

Oral cancer patients suffer pain at the site of the cancer. Calcitonin gene related polypeptide (CGRP), a neuropeptide expressed by a subset of primary afferent neurons, promotes oral cancer growth. CGRP also mediates trigeminal pain (migraine) and neurogenic inflammation. The contribution of CGRP to oral cancer pain is investigated in the present study. The findings demonstrate that CGRP-immunoreactive (-ir) neurons and neurites innervate orthotopic oral cancer xenograft tumors in mice. Cancer increases anterograde transport of CGRP in axons innervating the tumor, supporting neurogenic secretion as the source of CGRP in the oral cancer microenvironment. CGRP antagonism reverses oral cancer nociception in preclinical oral cancer pain models. Single-cell RNA-sequencing is used to identify cell types in the cancer microenvironment expressing the CGRP receptor components, receptor activity modifying protein 1 Ramp1 and calcitonin receptor like receptor (CLR, encoded by Calcrl). Ramp1 and Calcrl transcripts are detected in cells expressing marker genes for Schwann cells, endothelial cells, fibroblasts and immune cells. Ramp1 and Calcrl transcripts are more frequently detected in cells expressing fibroblast and immune cell markers. This work identifies CGRP as mediator of oral cancer pain and suggests the antagonism of CGRP to alleviate oral cancer pain.

Uncovering a new route to pain therapy

A complex network of many interacting mechanisms orchestrates immune and inflammatory responses. Among these, the cation channels of the transient receptor potential (TRP) family expressed by resident tissue cells, inflammatory and immune cells and distinct subsets of primary sensory neurons, have emerged as a novel and interrelated system to detect and respond to harmful agents. TRP channels, by means of their direct effect on the intracellular levels of cations and/or through the indirect modulation of a large series of intracellular pathways, orchestrate a range of cellular processes, such as cytokine production, cell differentiation and cytotoxicity. The contribution of TRP channels to the transition of inflammation and immune responses from a defensive early response to a chronic and pathological condition is also emerging as a possible underlying mechanism in various diseases. This review discusses the roles of TRP channels in inflammatory and immune cell function and provides an overview of the effects of inflammatory and immune TRP channels on the pathogenesis of human diseases.

A Novel Class of Transient Receptor Potential Melastatin 8 Agonists

In last decades, Transient Receptor Potential Vanilloid 1 (TRPV1) has been the target of a large number of scientific investigations. It has been identified as a polymodal transducer molecule on a sub-set of primary sensory neurons which responds to various endogenous and exogenous stimuli including noxious heat (more than 42°C), protons and vanilloids such as capsaicin, the hot ingredient of chilli peppers. In mammals, TRPV1 displays a wide tissue and cellular expression including both the peripheral and central nervous system, with broad distribution and functions, in physiological and pathological conditions. Its primary localisation in sensory neurons reveals its key nodal point in pain transmission pathways. Nowadays, it is clear that TRPV1 is involved in inflammation, pain perception and thermoregulation in the majority of animals, including humans. Recently, a lot of studies tried to investigate some analgesic treatments applied on TRPV1. The aim of this review is to give to the readers a short overview of the TRPV1 involvement in pain perception and possible therapeutic applications, highlighting this topic in species of interest in veterinary medicine.

The capsaicin receptor, transient receptor potential vanilloid type 1 ion channel (TRPV1), has been identified as a polymodal transducer molecule on a sub-set of primary sensory neurons which responds to various stimuli including noxious heat (> -42 degrees C), protons and vanilloids such as capsaicin, the hot ingredient of chilli peppers. Subsequently, TRPV1 has been found indispensable for the development of burning pain and reflex hyperactivity associated with inflammation of peripheral tissues and viscera, respectively. Therefore, TRPV1 is regarded as a major target for the development of novel agents for the control of pain and visceral hyperreflexia in inflammatory conditions. Initial efforts to introduce agents acting on TRPV1 into clinics have been hampered by unexpected side-effects due to wider than expected expression in various tissues, as well as by the complex pharmacology, of TRPV1. However, it is believed that better understanding of the pharmacological properties of TRPV1 and specific targeting of tissues may eventually lead to the development of clinically useful agents. In order to assist better understanding of TRPV1 pharmacology, here we are giving a comprehensive account on the activation and inactivation mechanisms and the structure-function relationship of TRPV1.

The regenerating gene/regenerating islet-derived (Reg) family is a group of small secretory proteins. Within this family, Reg type-III (Reg-III) consists of: Reg-IIIα, -β, -γ, and -δ. To elucidate the physiological relevance of Reg-III, we examined the localization and ontogeny of Reg-IIIβ and Reg-IIIγ in mice at different time points spanning from embryonic day 13.5 to 7 weeks old, using in situ hybridization and immunohistochemistry. Our results showed that Reg-IIIβ was expressed in specific subsets of primary sensory neurons and motor neurons, and that expression was transient during the embryonic and perinatal periods. Reg-IIIβ expression was also observed in absorptive epithelial cells of the intestine. In contrast, Reg-IIIγ expression was mainly observed in epithelial cells of the airways and intestine, but not in the nervous system, and expression levels showed a gradually increasing pattern along with development. In the airways Reg-IIIγ was expressed in goblet and Clara-like cells, whereas in the intestine Reg-IIIγ was expressed in the absorptive epithelial cells and Paneth cells, and was found to be expressed in development before these organs had been exposed to the outside world. The present findings imply that Reg-IIIβ and Reg-IIIγ expression is regulated along divergent pathways. Furthermore, we also suggest that expression of Reg-IIIγ in the airway and intestinal epithelia may occur to protect these organs from exposure to antigens or other factors (e.g., microbes) in the outer world, whereas the transient expression of Reg-IIIβ in the nervous system may be associated with the development of the peripheral nervous system including such processes as myelination.

Primary afferent "pain" fibers (nociceptors) are divided into subclasses based on distinct molecular and anatomical features, and these classes mediate noxious modality-specific contributions to behaviors evoked by painful stimuli. Whether the heat and capsaicin receptor transient receptor potential vanilloid-1 (TRPV1) is expressed heterogeneously across several sensory populations, or is selectively expressed by a unique nociceptor subclass, however, is unclear. Here we used two lines of Trpv1 reporter mice to investigate the primary afferent expression of TRPV1, both during development and in the adult. We demonstrate, using Cre-induced lineage tracing, that during development TRPV1 is transiently expressed in a wide range of dorsal root ganglion neurons, and that its expression is gradually refined, such that TRPV1 transcripts become restricted to a specific subset of peptidergic sensory neurons. Finally, the remarkable sensitivity that is characteristic of these reporter mice revealed an innervation of central and peripheral targets by TRPV1+ primary afferents in the adult that is considerably more extensive than has previously been appreciated.

Oncostatin M (OSM) is a member of the interleukin-6 cytokine family and regulates eg. gene activation, cell survival, proliferation and differentiation. OSM binds to a receptor complex consisting of the ubiquitously expressed signal transducer gp130 and the ligand binding OSM receptor subunit, which is expressed on a specific subset of primary afferent neurons. In the present study, the effect of OSM on heat nociception was investigated in nociceptor-specific gp130 knock-out (SNS-gp130-/-) and gp130 floxed (gp130fl/fl) mice.Subcutaneous injection of pathophysiologically relevant concentrations of OSM into the hind-paw of C57BL6J wild type mice significantly reduced paw withdrawal latencies to heat stimulation. In contrast to gp130fl/fl mice, OSM did not induce heat hypersensitivity in vivo in SNS-gp130-/- mice. OSM applied at the receptive fields of sensory neurons in in vitro skin-nerve preparations showed that OSM significantly increased the discharge rate during a standard ramp-shaped heat stimulus. The capsaicin- and heat-sensitive ion channel TRPV1, expressed on a subpopulation of nociceptive neurons, has been shown to play an important role in inflammation-induced heat hypersensitivity. Stimulation of cultured dorsal root ganglion neurons with OSM resulted in potentiation of capsaicin induced ionic currents. In line with these recordings, mice with a null mutation of the TRPV1 gene did not show any signs of OSM-induced heat hypersensitivity in vivo.The present data suggest that OSM induces thermal hypersensitivity by directly sensitizing nociceptors via OSMR-gp130 receptor mediated potentiation of TRPV1.

Moderate warming of mouse scrotum evokes avoidance behavior and phosphorylation of nuclear factor kappa B in a subset of primary sensory neurons

Correction for Cavanaugh et al., Distinct subsets of unmyelinated primary sensory fibers mediate behavioral responses to noxious thermal and mechanical stimuli

Functional tetrodotoxin-resistant Na + channels are expressed presynaptically in rat dorsal root ganglia neurons

Pain sensation occurs at multiple levels of the nervous system, involving a myriad of molecules and signaling pathways that contribute to the detection of noxious stimuli, and the modulation, initiation and propagation of electrical activity in nociceptors, a subset of primary sensory neurons. The fact that several types of ion channels or their splice variants are highly expressed in nociceptors and are critical for pain transduction has prompted scientists to examine their physiological roles in order to better understand the neuromolecular mechanisms of the pain pathway. Recent reports have demonstrated that TRPA1, a member of the mammalian transient receptor potential cation channel family, acts as a key chemical nocisensor in response to diverse chemical stimuli. The TRPA1 channel represents a new target for novel analgesics to specifically eliminate pain sensation of various stimuli.

For most organisms, food is only intermittently available; therefore, molecular mechanisms that couple sensation of nutrient availability to growth and development are critical for survival. These mechanisms, however, remain poorly defined. In the absence of nutrients, newly hatched first larval (L1) stage Caenorhabditis elegans halt development and survive in this state for several weeks. We isolated mutations in unc-31, encoding a calcium-activated regulator of neural dense-core vesicle release, which conferred enhanced starvation survival. This extended survival was reminiscent of that seen in daf-2 insulin-signaling deficient mutants and was ultimately dependent on daf-16, which encodes a FOXO transcription factor whose activity is inhibited by insulin signaling. While insulin signaling modulates metabolism, adult lifespan, and dauer formation, insulin-independent mechanisms that also regulate these processes did not promote starvation survival, indicating that regulation of starvation survival is a distinct program. Cell-specific rescue experiments identified a small subset of primary sensory neurons where unc-31 reconstitution modulated starvation survival, suggesting that these neurons mediate perception of food availability. We found that OCR-2, a transient receptor potential vanilloid (TRPV) channel that localizes to the cilia of this subset of neurons, regulates peptide-hormone secretion and L1 starvation survival. Moreover, inactivation of ocr-2 caused a significant extension in adult lifespan. These findings indicate that TRPV channels, which mediate sensation of diverse noxious, thermal, osmotic, and mechanical stimuli, couple nutrient availability to larval starvation survival and adult lifespan through modulation of neural dense-core vesicle secretion.

In the development and progression of hypertensive organ damage, hemodynamic factors such as high pressure, turbulent flow, and shear stress are thought to cause endothelial dysfunction and vascular remodeling. Nephrosclerosis may eventually result from a complex cascade of inflammatory and fibrotic processes. Research on novel therapeutic targets has, therefore, focused on regulatory systems that play a significant role for the regulation of blood pressure and volume homeostasis, as well as for modulating inflammation or fibrosis. The autonomic innervation of the kidney may be such a regulatory system but has been difficult to study at the molecular level. This issue of Hypertension contains a report by Wang et al1 that is an important step forward in that regard. The authors studied the transient receptor potential vanilloid type 1 (TRPV1) receptor, a member of the mammalian transient receptor potential channel superfamily. Transient receptor potential channels mediate the transmembrane flux of cations down their electrochemical gradients, thereby raising intracellular Ca2+ and Na+ concentrations and depolarizing the cell.2 The TRPV1 channel was identified by expression cloning using the hot pepper–derived vallinoid compound capsaicin as a ligand and is, therefore, referred to as the capsaicin or vallinoid receptor. TRPV1 channels are mainly expressed on a subset of primary afferent neurons, with unmyelinated (C-fibers) or thinly myelinated axons (Aδ-fibers). TRPV1 channels are not only sensitive to capsaicin but can be stimulated by thermal, acidic, chemical, or mechanical factors,3 as well as endogenous arachidonic acid derivates, such as anandamide.4 Wang et al1 demonstrated in a mouse model of deoxycorticosterone acetate (DOCA)-salt hypertension that deletion …

A subset of primary sensory neurons produces BDNF, which is implicated in control of nociceptive neurotransmission. We previously localized full-length trkB receptors on their terminals within lamina II. To functionally study these receptors, we here employed patch-clamp recordings, calcium imaging and immunocytochemistry on slices from 8-12 days post-natal rats. In this preparation, BDNF (100-500 ng/mL) enhances the release of sensory neurotransmitters (glutamate, substance P, CGRP) in lamina II by acting on trkB receptors expressed by primary afferent fibers of the peptidergic nociceptive type (PN-PAFs). Effect was blocked by trk antagonist K252a or anti-trkB antibody clone 47. A pre-synaptic mechanism was demonstrated after (i) patch-clamp recordings where the neurotrophin induced a significant increase in frequency, but not amplitude, of AMPA-mediated mEPSCs, (ii) real time calcium imaging, where sustained application of BDNF evoked an intense response in up to 57% lamina II neurons with a significant frequency rise. Antagonists of ionotropic glutamate receptors and NK(1) receptors completely inhibited the calcium response to BDNF. Reduction of CGRP (a specific marker of PN-PAFs) and substance P content in dorsal horn following BDNF preincubation, and analysis of the calcium response after depletion with capsaicin, confirmed that the neurotrophin presynaptically enhanced neurotransmitter release from PN-PAFs. This is the first demonstration that trkB receptors expressed by PN-PAF terminals in lamina II are functional during postnatal development. Implications of this finding are discussed considering that BDNF can be released by these same terminals and microglia, a fraction of which (as shown here) contains BDNF also in unactivated state.

The cell adhesion molecule L1 (L1-CAM) plays important functional roles in the developing and adult nervous systems. Here we show that peripheral nerve injury induced dynamic post-transcriptional alteration of L1-CAM in the rat dorsal root ganglia (DRGs) and spinal cord. Sciatic nerve transection (SCNT) changed the expression of L1-CAM protein but not L1-CAM mRNA. In DRGs, SCNT induced accumulation of the L1-CAM into the surface of somata, which resulted in the formation of immunoreactive ring structures in a number of unmyelinated C-fiber neurons. These neurons with L1-CAM-immunoreactive ring structures were heavily colocalized with phosphorylated p38 MAPK. Western blot analysis revealed the increase of full-length L1-CAM and decrease of fragments of L1-CAM after SCNT in DRGs. Following SCNT, L1-CAM-immunoreactive profiles in the dorsal horn showed an increase mainly in pre-synaptic areas of laminae I–II with a delayed onset and colocalized with growth-associated protein 43. In contrast to DRGs, SCNT increased the proteolytic 80-kDa fragment of L1-CAM and decreased full-length L1-CAM in the spinal cord. The intrathecal injection of L1-CAM antibody for the extracellular domain of L1-CAM inhibited activation of p38 MAPK and emergence of ring structures of L1-CAM immunoreactivity in injured DRG neurons. Moreover, inhibition of extracellular L1-CAM binding by intrathecal administration of antibody suppressed the mechanical allodynia and thermal hyperalgesia induced by partial SCNT. Collectively, these data suggest that the modification of L1-CAM in nociceptive pathways might be an important pathomechanism of neuropathic pain.

Alteration of the cell adhesion molecule CHL1 expression in a specific subset of primary afferent neurons and dorsal horn following nerve injury